JP2577179B2 - Quasi-resonant diode drive current source - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a diode driving current source, and more particularly to a quasi-resonant diode driving current source used for supplying power to a solid-state laser.

[0002]

BACKGROUND OF THE INVENTION Current controlled quasi-resonant converters are known in the motor art and are described in the literature (H. Le-Huy, IEEE Transactions on Industrial Eiectronics,
Vol. 38, No. 5, October 1991). This document describes a current controlled quasi-resonant converter for use in low and medium power variable speed drives using a switching reluctance motor. The device uses zero current switching to improve switching characteristics and provide effective control of the current in the motor windings. Further, quasi-resonant converters are described in another document (RB Ridley, IEEE).
E Transactions on POWER Electronics, Vol.6, No.1
, January 1991). This document describes a multiple loop control scheme for a quasi-resonant converter and various resonant buck converter configurations and circuits. The resonance converter operates at the resonance frequency of the LC resonance circuit to be used or a frequency near the resonance frequency. On the other hand, a quasi-resonant converter similarly uses an oscillating current by using an LC resonance circuit, but the operating frequency is not a resonance frequency but a low frequency distant from the resonance frequency. Is different. Therefore, a converter operating in such a manner as to be distinguished from a normal resonance converter is called a quassi-resonant converter.

According to laser technology, diode pumping has been selected for use in solid state laser systems due to its high electro-optical efficiency. Prior to the use of diode pumping, flash lamps were used as a pump source. Its typical system efficiency is 1-2%. This low efficiency is mainly due to its low electro-optical efficiency. The use of diode pumping results in a laser system efficiency of 10-15% due to its high electro-optical efficiency. The power being followed can be reduced by a factor of ten.

[0004]

Diode pumping requires a regulated high power pulsed current source to drive the pump diode. Typical current sources use a series power consumption regulator or a pulse width modulation (PWM) converter to control the output current. When used at high output currents, as required, for example, by diode-pumped lasers, both of these techniques result in high power losses and are therefore very inefficient.

In a series power consumption regulator, power is consumed by a voltage drop across a series current passing element, usually a transistor, and the power P is P = (V _in -V
_out ) × I _out Therefore, power loss is very high at high output current. PWM converters cause high switching losses in their switching transistors, especially in the reverse recovery of the catch diode and in switching losses in the catch diode. At high output currents, the reverse recovery current is very large, resulting in very high power losses.

Accordingly, it is an object of the present invention to provide a current source that is relatively efficient and is capable of providing a regulated current of high power pulses to a solid state diode pumped laser or similar device.

[0007]

According to the present invention, a quasi-resonant diode driven converter is used as a pulsed high power current source and is used to drive a light emitting diode or the like. The diode drive current source of the present invention can be used, for example, to drive a solid state light emitting diode used to pump a solid state laser. The output current of the quasi-resonant diode driven converter is detected and adjusted by the control loop to the level required by the light emitting diode. In a particular embodiment of the present invention, a zero current switched full wave quasi-resonant buck converter is developed to provide the pulsed high amplitude output current required to drive multiple light emitting diodes, which is Pump the laser crystal.

More specifically, in one embodiment of the present invention,
A power supply, a light emitting diode, and a quasi-resonant converter coupled between the power supply and the light emitting diode for supplying a pulse current to the light emitting diode. A current sensing device is provided for sensing the current through the light emitting diode, and control means is connected to the sensing means for adjusting the amplitude of the pulse current supplied to the light emitting diode.

Further, a laser drive circuit according to the present invention includes a charge supply source and a plurality of charge storage devices coupled to the charge supply source for storing charges. A plurality of light emitting diode arrays each having a plurality of light emitting diodes are coupled to the charge storage device. The plurality of diode driving circuits are respectively coupled to the plurality of light emitting diode arrays, and constitute a quasi-resonant diode driving pulse current source as described above.

[0010]

The use of a quasi-resonant diode driven converter provides a much higher conversion efficiency compared to a conventional laser current source. This high conversion efficiency reduces the input power drawn from the power supply and reduces the operation of the cooling device, thereby increasing the reliability of the current source. The improved efficiency is particularly effective at high power levels, which significantly reduces power consumption. The invention is of particular importance for the field of solid-state diode pumped lasers that require a high current, regulated pulsed current source. Without such an efficient power supply, diode-pumped lasers would not be practical.

[0011]

FIG. 1 shows a plurality of laser light emitting diode arrays each comprising a plurality of light emitting diodes 16;
FIG. 2 is a block diagram of a light emitting diode driving circuit 10 for a laser using a quasi-resonant diode driving current source 20 according to the present invention to drive 13, 14, and 15; Each of the laser light emitting diode arrays 13, 14, 15 is configured to pump a laser crystal (not shown), and the laser device using the laser crystal (not shown) includes two amplifiers and one laser crystal. It has an oscillator. Each laser light emitting diode array 13, 14, 15 has a plurality of separate laser light emitting diodes 16, which light emitting diodes 16 are one of the charge supply device 11 and the quasi-resonant diode driving current source 20.
Are connected in series. The protection diode 17 is connected in parallel with the series circuit of the light emitting diodes 16 and is used to protect the plurality of light emitting diodes 16 in the case of a reverse voltage. Multiple light emitting diodes with capacitor 12
Capacitance separation is performed between each of the sixteen. Capacitor 12 is used to store charge controlled by quasi-resonant diode drive current source 20 to energize laser light emitting diode arrays 13, 14, 15. Although a circuit similar to that of FIG. 1 is used in a conventional ordinary diode driving circuit, the present invention uses a quasi-resonant diode driving current source 20 as shown in detail in FIG. 2 as a driving current source. Are different. One of the ordinary diode drive circuits not using the quasi-resonant diode drive current source 20
Examples are models manufactured by Analog Modules
It is 778.

FIG. 2 is a schematic diagram of a quasi-resonant diode driving current source 20 according to the present invention used in the diode driving circuit 10 of FIG. FIG. 2 shows a zero current switch full wave buck converter as an example,
It should be understood that the quasi-resonant diode drive current source 20 of the present invention can be readily implemented with other types of converters.

As noted above, switching losses in a typical buck converter current source result in very large power losses, and such circuits are very inefficient as a current source. Therefore, a power conversion technique that minimizes switching loss is desired, and a quasi-resonant diode driving current source 20 as shown in FIG. 2 was developed. The diode drive current source 20 of this embodiment is a zero current switch quasi-resonant converter 21. The converter 21 utilizes the component parasitics or masks the component parasitics so that their effects are negligible.

The zero current switch quasi-resonant converter 21 comprises a power supply 22, which is coupled to a light emitting diode 31 through a series connected switch transistor 24 (Q1), a resonant inductor 27 (L1) and a filter inductor 28 (L2). Have been. A conventional power supply filter (not shown) can easily be used in the circuit of FIG. Diode 25 (CR
1) is coupled in parallel with the switch transistor 24.
Catch diode 29 (CR2) and resonance capacitor 30
(C1) is the resonance inductor 27 (L1) and the filter inductor 2
8 (L2) and the negative terminal of the power supply. A current sensor 32 senses the output current coupled to the light emitting diode 31 and is coupled by a detection line 33 to a quasi-resonant control device 26 which varies the switching frequency by changing the switching frequency.
1) Adjust the average value of the current flowing through.

Resonant inductor 27 (L1) provides a high impedance to switch transistor 24 (Q1) during the switching time, allowing for no loss in switching of switch transistor 24 (Q1). Resonant capacitor 30 (C1) masks the capacitance and reverse recovery of catch diode 29 (CR2), thus eliminating the switching losses of catch diode 29 (CR2). This configuration allows for essentially lossless switching. Detailed circuit descriptions of resonant converters are described in various documents (for example, Unitrode Integrated
"Linear" published by Circuit Corporation in April 1990.
Integrated Circuits Data and Applications Handboo
k).

The operation of the quasi-resonant current source 20 will be described in detail below with reference to FIGS. 3 and 4 showing operation waveforms of the circuit. Initially assume a zero state. The switch transistor 24 is turned on, and the input voltage is supplied to both ends of the resonance inductor 27. Since the resonant inductor 27 is a switch transistor 24 in series, the rise of the current V _in / L1
Limited by The switch transistor 24 is switched on with essentially zero collector (or drain) current, and the switching losses are zero. The input voltage is supplied to a very low damping LCR low impedance tank circuit comprising a resonant inductor 27 and a resonant capacitor 30.
From turn-on, the input current rises and flows through the tank circuit through switch transistor 24 in a sine wave. Resonant capacitor 30 is charged by the input current to 2V _in. The input current continues to change with a sine wave, the polarity is inverted, and flows through the diode 25 to the power supply 22 in the reverse direction. The resonance capacitor 30 is discharged by this reverse current. Switch transistor 24
Is switched off during the time that this resonant capacitor 30 is discharged. Therefore, there is no current flowing through the switch transistor 24 at this time, so that the loss is also zero when the switch transistor 24 is off. The input current then goes to zero again and diode 25 is switched off. The next cycle begins, switch transistor 24 is turned on again, and the process is repeated. Resonant capacitor 30 is charged (and discharged) once each cycle.

As the cycle repeats, filter inductor 28 begins to conduct current. The above-described charging of the resonance capacitor 30 supplies a current by the voltage across the filter inductor 28 through the impedance of the light emitting diode 31. Current rise (di / dt) in this inductor 28
Is proportional to the voltage (VC1) supplied to the resonance capacitor 30 times the cycle speed. Therefore, the current in inductor 28,
Therefore, the current of the light emitting diode 31 is controlled by changing the frequency at which the switch transistor 24 is switched. The output current is detected and the control loop changes the operating frequency to regulate the output current.

Operation at steady state output current is slightly different from that described above. A description will be given with reference to FIG. 5 which shows a steady state operation waveform of the pseudo resonance diode drive current source 20. It is assumed that the converter has reached a steady state before the times shown in these figures. Switch transistor
24 is off, the input current (I _in ) is zero, the voltage across the resonant capacitor 30 (VC 1) is zero (actually one diode drop below zero),
The output current (I _out ) flows through the filter inductor 28 and the catch diode 29. Output current is sensor 32
The switch transistor 24 is turned on because it has been detected and has fallen. As the output current I _out continues to flow through the resonant inductor 27 and the diode 25, the voltage (VC1) remains at zero volts. Input voltage V
_{When in} is applied to both ends of the resonance inductor 27, I _in rises linearly to I _out , and shortly thereafter, I _in > I _out. A current is generated that flows into 30 and returns through diode 25 to the power supply. The output current acts as a braking resistor to the resonant tank circuit, and the current through diode 25 is much smaller than at start. When the voltage (VC1) reaches zero volts, it begins to flow through the catch diode 29 I _out again. Cycle when the I _in returns to zero and change is completed.

The quasi-resonant diode drive current source 20 was simulated using conventional SPICE-based analysis. This simulation produced the waveforms shown in FIGS. Simulation results demonstrate the features and benefits described above.

An experimental example of the quasi-resonant diode drive current source 20 has been assembled and tested. The performance of this example is in good agreement with the predicted performance. Efficiency measurements were made and the calculated efficiency was around 85-90%. It is recognized that the conversion efficiency of the quasi-resonant diode drive current source 20 can be improved to about 95%.

Thus, the present invention has described a quasi-resonant current source for use in powering a new and improved solid state laser.
The above embodiments are merely illustrative of some of the many embodiments applying the principles of this invention, and many other modifications may be made by those skilled in the art without departing from the scope of the invention. It should be understood that this can be done.

[Brief description of the drawings]

FIG. 1 is a block diagram of a laser diode drive circuit using a quasi-resonant diode drive current source according to one embodiment of the present invention.

FIG. 2 is a circuit diagram of a quasi-resonant diode driving current source according to one embodiment of the present invention.

FIG. 3 is an operation waveform diagram of the quasi-resonant diode driving current source of FIG. 2;

FIG. 4 is an operation waveform diagram of the quasi-resonant diode driving current source of FIG. 2;

FIG. 5 is an operation waveform diagram of the pseudo-resonant diode driving current source of FIG. 2 in a steady state.

[Explanation of symbols]

11: charge supply source, 20: pseudo resonance current source, 26: pseudo resonance control device, 31: light emitting diode.

 ────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Joseph H. Ullman, Nashawena Court, Cypress, 90630, California, USA 11365 (56) References JP-A-55-107282 (JP, A)

Claims (7)

(57) [Claims] A power supply, a light emitting diode, a quasi-resonant converter coupled between the power supply and the light emitting diode for providing a pulse current to the light emitting diode, and sensing means for sensing a current through the light emitting diode; Coupled to the means and based on the output of the sensing means
Control means for controlling the quasi-resonant converter to adjust the amplitude of the pulse current supplied to the light emitting diode. 2. A quasi-resonant converter comprising a zero current switch full wave quasi-resonant buck converter.
The described device. 3. A quasi-resonant converter comprising: a switch transistor having a diode coupled in parallel; a resonant inductor; a filter inductor; a resonant capacitor and a catch diode connected in parallel to a series circuit of the filter inductor and the light emitting diode. 3. The device according to claim 2, comprising: 4. A charge supply source; charge storage means coupled to the charge supply source for storing charge; a plurality of light emitting diode arrays each having a plurality of light emitting diodes coupled to the charge storage means; emitting diode and a respective combined with that <br/> plurality of diode driver to the array, the diode drive circuit to include a quasi-resonant converter
A laser drive circuit comprising a diode drive pulse current source . 5. A diode driving pulse current source comprising said quasi-resonant converter is coupled between a charge storage means and a selected one of a plurality of light emitting diode arrays to pulse a light emitting diode array. A quasi-resonant converter for supplying current; sensing means for sensing current through the selected light emitting diode array; and control coupled to the sensing means for adjusting the amplitude of the pulse current supplied to the selected light emitting diode array. 5. The driving circuit according to claim 4, further comprising: 6. The quasi-resonant converter comprises a zero current switch full wave quasi-resonant buck converter.
The driving circuit as described. 7. A quasi-resonant converter, comprising: switching means coupled between the charge storage means and a selected one of the plurality of light emitting diode arrays; and a switching means coupled between the switching means and a selected one of the plurality of light emitting diode arrays. 7. The driving circuit according to claim 6, further comprising: a resonance inductor and a filter inductor coupled in series to the first and second components; and a catch diode and a resonance capacitor coupled in parallel to the filter inductor and a selected one of the plurality of light emitting diode arrays. .